Systems and methods for reading data from a storage medium

ABSTRACT

A system for reading data from a storage medium. The system includes a reader and a data determination circuit. The reader is configured to receive a first signal from a first position relative to the storage medium and read a second signal from a second position relative to the storage medium. Each of the first signal and the second signal includes a combination of first data stored in a first track and second data stored in a second track. The data determination circuit is configured to determine third data stored at a predetermined position using the combination of the first data stored in the first track and the second data stored in the second track as received in the first signal and the combination of the first data stored in the first track and the second data stored in the second track as received in the second signal.

CROSS-REFERENCE TO RELATED APPLICATIONS

The present disclosure is a continuation of U.S. patent application Ser. No. 13/943,726 (now U.S. Pat. No. 9,082,418), filed on Jul. 16, 2013, which claims the benefit of U.S. Provisional Application No. 61/671,832, filed on Jul. 16, 2012. The entire disclosures of the applications referenced above are incorporated herein by reference.

FIELD

Embodiments relate generally to methods for reading data from a storage medium using a reader head and to storage devices.

BACKGROUND

The amount of data to be stored on data storage devices is increasing. Thus, it may be desired to provide data storage devices with a high data storage capacity.

SUMMARY

According to various embodiments, a method for reading data from a storage medium using a reader (with one reader head or with a plurality (for example an array) of reader heads, for example multiple readers on a single slider) may be provided. The method may include: reading a first signal with a reader head of the reader at a first position of the storage medium; reading a second signal with a reader head of the reader at a second position of the storage medium; and determining data stored at a pre-determined position of the storage medium based on the first signal and based on the second signal. The reading of the signal can be sequential (for example using a single reader head) or parallel (for example using multiple reader heads in a slider).

According to various embodiments, a storage device may be provided. The storage device may include: a storage medium; a reader (for example including one reader head or multiple reader heads; in other words: a plurality of read heads) configured to read a first signal with a reader head of the reader at a first position of the storage medium and configured to read a second signal with a reader head of the reader at a second position of the storage medium; and a data determination circuit configured to determine data stored at a predetermined position of the storage medium based on the first signal and based on the second signal.

BRIEF DESCRIPTION OF DRAWINGS

In the drawings, like reference characters generally refer to the same parts throughout the different views. The drawings are not necessarily to scale, emphasis instead generally being placed upon illustrating the principles of the invention. In the following description, various embodiments are described with reference to the following drawings, in which:

FIG. 1A shows a flow diagram illustrating a method for reading data from a storage medium using a reader (with one reader header or with a plurality of reader heads) in accordance with an embodiment;

FIG. 1B shows a storage device in accordance with an embodiment;

FIG. 2 shows a schematic illustration of a wide reader for shingled tracks on a recording medium in accordance with an embodiment;

FIG. 3 shows an illustration of a de-convolution method for a fixed-offset adjacent track subtraction method in accordance with an embodiment;

FIG. 4 shows a diagram of simulated shingle write pattern in accordance with an embodiment;

FIG. 5 shows a simulated read back from a reader which is wider than the track pitch in accordance with an embodiment;

FIG. 6 shows an illustration of signal processing of a fixed-offset adjacent track subtraction method on simulated signal in accordance with an embodiment;

FIG. 7 shows an illustration of recovered simulated written signal in accordance with an embodiment;

FIG. 8 shows an illustration of a read back signal X₁ and X₂ over 2 shingle tracks in accordance with an embodiment;

FIG. 9 shows an illustration of a general schematic diagram of deconvolution based on amplitude coefficient estimation method in accordance with an embodiment;

FIG. 10 shows an illustration of a schematic diagram of deconvolution based on amplitude coefficient estimation method in sequential plurality reading in accordance with an embodiment;

FIG. 11 shows an illustration of a first phase and amplitude coefficient detector scheme implementing a cross-correlation method or matching filter method;

FIG. 12 shows an illustration of an extraction of continuous PES signals out from high sampling amplitude coefficient;

FIG. 13 shows a dual stage PES Servo configuration;

FIG. 14 shows a second phase and amplitude coefficient scheme including a preamble as phase synchronization and introducing an additional multi-frequency data pattern in data region for amplitude coefficient detection;

FIG. 15 shows a diagram and a signal associated to the second scheme;

FIG. 16 shows a signal comparison between original track signal and reconstructed track signal;

FIG. 17 shows a SNR comparison for the case NR (No signal recovery apply), 1 and 2 (shingle track signal recovered using the scheme 2), NT31 (original shingle track with no adjacent interference) and WT31 (wide track signal);

FIG. 18 shows a third phase and amplitude coefficient detection scheme wherein a buried layer dedicated servo can generate both PES and phase synchronization signal for wide reader magnetic recording; and

FIG. 19 shows an illustration of a writing scheme for wide reader in shingle magnetic recording in accordance with an embodiment;

FIG. 20 illustrates a system for real time spindle speed variation and relative head-disk motion measurement in accordance with a present embodiment:

FIG. 21 illustrates a double filter variant of the system of FIG. 20 in accordance with the present embodiment:

FIG. 22 illustrates a graph of filtered signals of the variant system of FIG. 21 in accordance with the present embodiment;

FIG. 23, comprising FIGS. 23A, 23B, 23C, and 23D, illustrates experimental results from the system of FIG. 20 in accordance with the present invention, wherein FIGS. 23A and 23B show experimental results obtained using the system of FIG. 20 on an air bearing spindle with a measured spindle speed variation and FIGS. 23C and 23D show experimental results obtained using the system of FIG. 20 for measurements on a hard disk drive (HDD) product;

FIGS. 24A and 24B illustrate experimental results obtained using the system of FIG. 21 for measurements on the HDD product of FIGS. 23C and 23D in accordance with the present invention;

FIG. 25 illustrates a cutaway view of a read-write head over disk media in accordance with the present invention;

FIG. 26 illustrates a top planar view of the reader head of FIG. 25 superimposed over tracks of a servo layer of the disk media of FIG. 25 in accordance with the present embodiment;

FIG. 27, comprising FIGS. 27A and 27B, illustrates block diagrams of synchronization signal generation and processing for detection of downtrack vibration, spindle speed variation and jitter in accordance with the present embodiment, wherein FIG. 27A depicts a block diagram of the synchronization signal generation and FIG. 27B depicts a block diagram of the synchronization signal processing;

FIGS. 28A and 28B illustrate a first set of simulation results of the synchronization signal processing of FIG. 27B in accordance with the present embodiment;

FIG. 29 illustrates a second set of simulation results of the synchronization signal processing of FIG. 27B in accordance with the present embodiment;

FIG. 30 illustrates spinstand simulation results of the synchronization signal processing of FIG. 27B in accordance with the present embodiment;

FIG. 31 illustrates a graph of a normal synchronization signal and a detected synchronization signal in a speed increase situation in accordance with the present invention;

FIG. 32 illustrates a block diagram of position error signal (PES) generation and flying height signal generation in accordance with the present invention;

FIG. 33 illustrates Wallace equation generation in accordance with the present embodiment;

FIG. 34, comprising FIGS. 34A and 34B, illustrates a graph of touchdown curves in accordance with the present embodiment, wherein FIG. 34A depicts a touchdown curve using flying height signals averaged over one hundred measurements and FIG. 34B depicts a touchdown curve using an instantaneous flying height signal measurement;

FIG. 35 illustrates a graph of experimental results for off-track variations of the flying height signal measured in accordance with the present embodiment;

FIG. 36, comprising FIGS. 36A and 36B, illustrates simulation results of flying height signals under various conditions in accordance with the present embodiment wherein FIG. 36A depicts the flying height signal vibration prior and acoustic emissions (AEs) and FIG. 36B depicts root mean square values of the flying height signal as well as AE sensor signals;

FIG. 37 illustrates a graph of a change in the flying height signal from thermal flying height control (TFC) actuation at different altitudes in accordance with the present embodiment; and

FIG. 38 illustrates a conventional graph of the curve of flying height versus TFC actuation as it varies at different altitudes.

DESCRIPTION

Embodiments described below in context of the devices are analogously valid for the respective methods, and vice versa. Furthermore, it will be understood that the embodiments described below may be combined, for example, a part of one embodiment may be combined with a part of another embodiment.

In this context, the storage device as described in this description may include a memory which is for example used in the processing carried out in the storage device. A memory used in the embodiments may be a volatile memory, for example a DRAM (Dynamic Random Access Memory) or a non-volatile memory, for example a PROM (Programmable Read Only Memory), an EPROM (Erasable PROM), EEPROM (Electrically Erasable PROM), or a flash memory, e.g., a floating gate memory, a charge trapping memory, an MRAM (Magnetoresistive Random Access Memory) or a PCRAM (Phase Change Random Access Memory).

In an embodiment, a “circuit” may be understood as any kind of a logic implementing entity, which may be special purpose circuitry or a processor executing software stored in a memory, firmware, or any combination thereof. Thus, in an embodiment, a “circuit” may be a hard-wired logic circuit or a programmable logic circuit such as a programmable processor, e.g. a microprocessor (e.g. a Complex Instruction Set Computer (CISC) processor or a Reduced Instruction Set Computer (RISC) processor). A “circuit” may also be a processor executing software, e.g. any kind of computer program, e.g. a computer program using a virtual machine code such as e.g. Java. Any other kind of implementation of the respective functions which will be described in more detail below may also be understood as a “circuit” in accordance with an alternative embodiment.

The amount of data to be stored on data storage devices is increasing. Thus, it may be desired to provide data storage devices with a high data storage capacity.

Reducing the bit aspect ratio (BAR) may be a way to further increase the areal density of HDD (hard disk drives) in the future. Shingled writing with a sharp field gradient may be a promising approach to further reduce the track pitch for higher KTPI (or kTPI, or kilo TPI, wherein TPI may stand for tracks per inch). The reader width may be a determination factor for achievable areal density. With noise limitation and also fabrication tolerance limit, the further reduction of the track width of a reader may be an issue with a big challenge, especially, reducing BAR towards 1. According to various embodiments, devices and methods may be provided to enable reading data from a track pitch which is narrower than its reader size.

According to various embodiments, devices and methods may be provided for shingle reading with a wide reader.

FIG. 1A shows a flow diagram 100 illustrating a method for reading data from a storage medium using a reader in accordance with an embodiment. The reader may include for example with one reader head or a plurality of reader heads, for example multiple readers on a single slider. In 102, a first signal may be read with a reader head of the reader at a first position of the storage medium. In 104, a second signal may be read with a reader head (for example the same reader head used for reading a the first position of the storage medium, or another reader head of the reader) at a second position of the storage medium. In 106, data stored at a pre-determined position of the storage medium may be determined based on the first signal and based on the second signal. The same procedure can be achieved by using multiple readers head to pick up multiple location signals at one read process. The multiple read heads may have a fixed reader offset in both down track and cross track. This may provide a simple way for reconstructing the narrower track information from wide reader.

In other words, in a method according to various embodiments, a plurality of readings may be made, wherein a reader head may be at different positions for each of the plurality of readings (for example at a first position for the first reading, at a second position for the second reading, and so on). Then, based on the plurality of readings, data that is stored on one pre-determined position of the storage medium may be determined based on the plurality of readings. The plurality of readings can be based on multiple read heads. According to various embodiments, in a single reader head (in other words: in a reader with only one reader head) signals may be read sequentially in a plurality reads. In a multiple readers head (in other words: in a head with a plurality of reader heads) signals may be read parallel in a plurality (parallel or simultaneous) reads. Multiple readers head mean many that there is provided a plurality of reader sensors in one head. Each reader may pick up a signal at different location simultaneously.

According to various embodiments, it may be understood that the reader head at a position may be understood as the center of the reader head on (or above) the position of the storage medium.

The storage medium may for example be a magnetic storage medium, for example a hard disc drive.

According to various embodiments, the storage medium may include a plurality of tracks. Each track may have a width (or a pitch) smaller than a width of a reader head of the reader.

According to various embodiments, for at least one of the first position or the second position a reader head of the reader may cover a first track and a second track.

According to various embodiments, the pre-determined position may include or may be one of a pre-determined position on the first track or a pre-determined position on the second track.

According to various embodiments, the first track and the second track may be adjacent.

According to various embodiments, the method may further include: reading a plurality of signals. For each signal, a reader head of the reader may be at a different position of the storage medium. The method may further include determining data stored at the predetermined position of the storage medium based on the plurality of signals. For example a multiple readers head may be used to pick up multiple signals at different location.

According to various embodiments, the method may further include: determining the data stored at the pre-determined position of the storage medium based on a deconvolution.

According to various embodiments, the method may further include: reading a frequency burst signal with a reader head of the reader at a position of the storage medium, wherein the position includes a frequency burst provided before a data track on the storage medium. According to various embodiments, the method may further include determining the data stored at the pre-determined position of the storage medium may further be based on the frequency burst signal.

According to various embodiments, the storage medium may include a plurality of tracks having a width (or a pitch) smaller than a width of a reader head of the reader; and the storage medium may include at least one track having a width (or a pitch) equal to or larger than the width of the reader head.

According to various embodiments, the first position may be different from the second position.

According to various embodiments, determining of the data stored at a predetermined position of the storage medium may further be based on determining an amplitude coefficient, the amplitude coefficient indicating a contribution of data stored at the first position of the recording medium.

According to various embodiments, determining of the data stored at a predetermined position of the storage medium may further be based on determining an amplitude coefficient, the amplitude coefficient indicating a contribution of data stored at the second position of the recording medium.

According to various embodiments, determining of the data stored at a predetermined position of the storage medium may further be based on determining a phase offset of data stored at the first position of the recording medium.

According to various embodiments, determining of the data stored at a predetermined position of the storage medium may further be based on determining a phase offset of data stored at the second position of the recording medium.

FIG. 1B shows a storage device 108 in accordance with an embodiment. The storage device 108 may include a storage medium 110. The storage device 108 may further include a reader 112 (for example including one reader head or a plurality of reader heads) configured to read a first signal with a reader head of the reader at a first position of the storage medium and configured to read a second signal with a reader head (for example the same reader head used for reading a the first position of the storage medium, or another reader head of the reader) at a second position of the storage medium. The storage device 108 may further include a data determination circuit 114 configured to determine data stored at a pre-determined position of the storage medium based on the first signal and based on the second signal. The storage medium 110, the reader 112, and the data determination circuit 114 may be coupled with each other, like indicated by lines 116, for example electrically coupled, for example using a line or a cable, and/or mechanically coupled.

According to various embodiments, it may be understood that the reader head at a position may be understood as the center of the reader head on (or above) the position of the storage medium.

The storage medium may for example be a magnetic storage medium, for example a hard disc drive.

According to various embodiments, the storage medium 110 may include a plurality of tracks, each track having a width (or a pitch) smaller than a width of a reader head of the reader.

According to various embodiments, for at least one of the first position or the second position a reader head of the reader may cover a first track and a second track.

According to various embodiments, the pre-determined position may include or may be one of a pre-determined position on the first track or a pre-determined position on the second track.

According to various embodiments, the first track and the second track may be adjacent.

According to various embodiments, the reader 112 may further be configured to read a plurality of signals. For each signal, a reader head of the reader 112 (for example the same reader head (for example the single reader head of the reader) or different reader heads of the reader) may be at a different position of the storage medium 110. The determination circuit 114 may further be configured to determine data stored at the pre-determined position of the storage medium 110 based on the plurality of signals.

According to various embodiments, the determination circuit 114 may further be configured to determine the data stored at the pre-determined position of the storage medium 110 based on a de-convolution.

According to various embodiments, the reader 112 may further be configured to read a frequency burst signal with a reader head of the reader 112 (for example the same reader head (for example the single reader head of the reader) or different reader heads of the reader) at a position of the storage medium including a frequency burst provided before a data track on the storage medium 110. The determination circuit may further be configured to determine the data stored at the pre-determined position of the storage medium further based on the frequency burst signal.

According to various embodiments, the storage medium 110 may include a plurality of tracks having a width (or a pitch) smaller than a width of a reader head of the reader 112. The storage medium 110 may or may not include at least one track having a width (or a pitch) equal to or larger than the width of the reader head 112.

According to various embodiments, the first position may be different from the second position.

According to various embodiments, the determination circuit 114 may further be configured to determine the data stored at a pre-determined position of the storage medium further based on determining an amplitude coefficient, the amplitude coefficient indicating a contribution of data stored at the first position of the recording medium.

According to various embodiments, the determination circuit 114 may further be configured to determine the data stored at a pre-determined position of the storage medium further based on determining an amplitude coefficient, the amplitude coefficient indicating a contribution of data stored at the second position of the recording medium.

According to various embodiments, the determination circuit 114 may further be configured to determine the data stored at a pre-determined position of the storage medium further based on determining a phase offset of data stored at the first position of the recording medium.

According to various embodiments, the determination circuit 114 may further be configured to determine the data stored at a pre-determined position of the storage medium further based on determining a phase offset of data stored at the second position of the recording medium.

A shingled magnetic recording (SMR) zone may include a plurality of shingled or overlapping tracks. For instance, a first track may be overlapped by a second track immediately adjacent (i.e. contiguous) to the first track and the second track may be overlapped by a third track immediately adjacent (i.e. contiguous) to the second track. The width of a writing element may be larger than the track pitch (i.e. the non-overlapped portions of the width of a data track).

According to various embodiments, a de-convolution method may be provided to enable a larger reader to read data from track pitch which is narrower than its reader size. Simulation results and experimental data will be described below to demonstrate the feasibility of the various embodiments. Furthermore, according to various embodiments, a subsequent suitable shingle writing scheme and an implementation of correlation ratio by using a dedicated frequency burst before a data track may be provided, like will be described in more detail below.

FIG. 2 shows a schematic illustration 200 of a reader for shingled tracks on a recording medium. In the shingled magnetic recording, a shingled track (for example a first shingled track 204, a second shingled track 206, and a third shingled track 208) may be designed to be narrower than the reader width (for example as indicated by an exemplary size of reader head 210) as shown in FIG. 2. It will be understood that although three shingled tracks 204, 206, and 208 are shown in FIG. 2, any number of shingled tracks may be provided. At the last track of shingled zone, the track 202 may be wider than the reader (or reader head) such that the reader may reproduce the integrity single track signal. This signal may be called the reference track signal. When the reader moves to the shingled tracks, the reader covers 2 tracks in one reading. Subsequently, the reader picks up a number of tracks of data or a page of data. According to various embodiments, a de-convolution process may be applied to get the data back (in other words: to determine the data stored in the recording medium).

For example, at a first position 212, the reader may read a first signal from the wide track 202 only. The first signal may correspond to the data stored in the wide track 202. At a second position 214, the reader may read a second signal which may be a combination or a mixture of signals from (or stored in) the wide track 202 and from (or stored in) the first shingled track 204. By knowing the signal from the wide track 202, the data stored in the first shingled track 204 may be reconstructed. At a third position 216, the reader may read a third signal which may be a combination or a mixture of signals from (or stored in) the first shingled track 204 and from (or stored in) the second shingled track 206. By knowing the signal from the first shingled track 202, the data stored in the second shingled track 206 may be reconstructed. At a fourth position 218, the reader may read a fourth signal which may be a combination or a mixture of signals from (or stored in) the second shingled track 206 and from (or stored in) the third shingled track 208. By knowing the signal from the second shingled track 204, the data stored in the third shingled track 208 may be reconstructed.

A de-convolution method can be either using a fixed-offset adjacent track subtraction method or amplitude coefficient estimation method to reconstruct the shingle track information.

FIG. 3 illustrates an example of a read back process of a de-convolution method. For example, a fixed-offset adjacent track subtraction method may be shown. If the magnetic reader width (MRW 304, or short “reader width” or “read width”), which for example may be measured in nm, is defined to be larger than the Magnetic shingle Track width (MTW 302, or short “track width”), which for example may be measured in nm, the equation of the read back signal X_(n) at location n may be

$\begin{matrix} {X_{n} = {{{A_{n}T_{1}} + {B_{n}T_{2}}} = {{\frac{{M\; R\; W} - {nM}}{M\; R\; W}T_{1}} + {\frac{nM}{\; {M\; R\; W}}T_{2}}}}} & (1) \end{matrix}$

where A may be the ratio of the amplitude signal contributed by a first data track, for example the data track T₁, and B may be the ratio of the amplitude signal contributed by a second data track, for example the data track T₂, wherein M 306 may be a step size (which may for example be measured in nm), n may be a step index, nM may be an offset (for example measured in nm) from the adjacent read, nM may be smaller than or equal MTW 302 (in other words: nM≦MTW), and A+B=1 (for example to normalize against MRW 304). For this example scheme, the MRW 304 may be larger than MTW 302 (of the second track T₂). But MRW 304 may be smaller than the MTW of T₁ (of the first track). The first MTW may be larger than MRW to provide a good signal without adjacent track interference for the subsequent track data recovery. Furthermore, it will be understood that X_(n) corresponds to an n step offset from an initial position.

In the following, a fixed-offset adjacent track subtraction method according to various embodiments will be described.

According to various embodiments, a method may be provided which takes the subtraction of two adjacent tracks read back signal with a known read offset. Generic equations derived from equation (1) may be shown as below:

$\begin{matrix} {{X_{n} - X_{n - 1}} = {{{- \frac{M}{M\; R\; W}}T_{1}} + {\frac{M}{M\; R\; W}T_{2}}}} & (2) \\ {{X_{n} - X_{0}} = {{{- \frac{nM}{M\; R\; W}}T_{1}} + {\frac{nM}{M\; R\; W}T_{2}}}} & (3) \end{matrix}$

It will be understood that the equations (2) and (3) may be derived from equation (1). The only different of them may be the step size or read offset.

Equation (2) illustrates the results of direct subtraction of 2 adjacent track with a known read offset between the signal. Equation (3) shows a special case where X₀ in equation may be referring to the signal only solely is contributed by the wide track T₁. Equations (2) and (3) may have a unique characteristic whereby the coefficient of T₁ and T₂ may be equal. The coefficient is defined as ratio of read offset to MRW. Substituting the known T₁ from reference track, X₀, T₂ may be reconstructed.

A simulation may be carried out to demonstrate the devices and methods according to various embodiments.

FIG. 4 shows an illustration 400 of a simulated shingle writing scheme which includes 5 data track, T₁ to T₅ (for example T₁ (402), T₂ (404), T₃ (406), T₄ (408), and T₅ (410)).

T1 may be the last shingle writing zone (which may also be referred to as the reference track) where the MTW may be set to be 12 units (arbitrary unit length) whereas the track width of the other tracks may be set to be 6 units. In this simulation, the MRW may be assumed to be same size as reference track width, 12 units.

FIG. 5 shows an illustration 500 of a mapping of the reader's read back signal X_(n) by moving 1 unit/step using equation 1. The resultant X_(n) is later subtracted by X_(n−1) (equation 2 and 3) as described in the fixed-offset adjacent track subtraction method. FIG. 6 shows the resultant processed signal of fixed-offset adjacent track subtraction method as in the illustration 600. Subsequently T₂ to T₅ signal may be reconstructed as shown in illustration 700 of FIG. 7. By solving the equation.

In the following, deconvolution by amplitude coefficient estimation method according to various embodiments will be described. For example, X_(n)=AT₁+BT₂; and the fixed offset adjacent track method according to various embodiments as described above does not need to know what is component A and B. By subtracting X_(n) to X_(n−1), it may be solved for the T₁ and T₂. In the amplitude coefficient estimation method according to various embodiments, a method to estimate A and B may be used in order to solve or reconstruct the T₁ and T₂. According to various embodiments, the fixed offset adjacent track method may use a multiple reader configuration.

FIG. 8 shows the illustration 800 of a read back signal X₁ and X₂ over 2 shingle tracks T₁ and T₂:

X ₁ =aT ₁ +bT ₂

X ₂ =cT ₁ +dT ₂  (4)

Equation (4) can be solved to reconstruct T₁ and T₂ if coefficient a, b, c and dare accurately estimated. Equation 5 shows the reconstructed shingle track T₁ and T₂.

$\begin{matrix} {{T_{1} = \frac{X_{1} - {bT}_{2}}{a}}{T_{2} = \frac{X_{2}}{{c\left( \frac{X_{1} - b}{a} \right)} + }}} & (5) \end{matrix}$

FIG. 9 shows an illustration 900 of general schematic of de-convolution method using the amplitude coefficient estimation method according to various embodiments. For illustration purpose, the scheme shows only 2 read back signals 902 (for example X₁ and X₂) to describe the working principle. According to various embodiments, the numbers of read back signals may not be limited. The 2 input signal may be sequentially read by a single reader head (sequential plurality read) or parallel read by multiple reader head (parallel plurality read). In real HDD application, signal X₁ and X₂ may be subjected to down track jitter noise and cross track positioning jitter (amplitude coefficient). A de-convolution process may require that both signals are phase synchronized in down track direction and track positioning jitter needs to be captured in the track amplitude coefficient a, b, c and d. The individual read back signal may go through a phase detector and amplitude coefficient detector 904 to estimate phase offset and a, b, c, d value. The phase offset of X₂ may be adjusted by a phase adjuster 906 according to X₁ to produce synchronized signal. T₁ and T₂ may be reconstructed (for example by deconvolution 908 following the de-convolution process as described in equation (5).

In sequential plurality reading, a de-convolution scheme may utilize the benefits of inherent wide track of shingle write as shown in illustration 1000 of FIG. 10. If the input signal from wide track (as determined in 1004), the read back signal X may directly be store in a memory 1006 as data track T₁. Subsequently, a read back signal X_(n) from shingle track may go through a phase detector and amplitude coefficient detector 1008 to determine phase offset of X_(n) with respect to Tn from memory and estimate the amplitude coefficient, a and b. Output of the detector will go through a phase and amplitude adjuster 1010 to produce synchronized signal before deconvoluting (in 1012) to reconstruct track info of T_(n+1). The scheme will continue to use T_(n+1) to reconstruct the next track signal.

There may be many ways to determine the phase offset and amplitude coefficient. Various embodiments will be described. Most of the following description is based on the scheme illustrated in FIG. 10. but the principle illustrated may also be applied in scheme illustrated in FIG. 9.

FIG. 11 shows a phase and amplitude detector scheme 1100 using cross-correlation method or matching filter method to recover the signal. The reference signal X₁ in memory 1102 may first cross-correlate (or match) itself using a match filter 1104 to produce a reference amplitude, A₀. Subsequence shingle read signal X₂ may match with the reference signal X₁ (for example using a further match filter 1106) to produce the phase difference P₁ and amplitude A₁. The amplitude coefficient, a may be a normalization of amplitude A₁ with respect to A₀. After the phase and amplitude adjuster, the shingle track data may be reconstructed.

The matching filter scheme may have additional benefits. If we divide the reference data and shingle data into smaller section as shown in illustration 1200 of FIG. 12, a higher sampling of amplitude coefficient a_(i)([A₁/A₀]_(i)) may be obtained. The amplitude coefficient may

translate into the position error signal (PES). Thus, a continuous PES system may be extracted from the arbitrary data pattern in the shingle reading system. A dual stage PES servo control system 1300 in FIG. 13 may then be provided. During the wide track read back, the continuous servo from arbitrary data pattern may not available. The conventional drive servo may be applied as the wide track requires less TPI (tracks per inch) resolution. When the head is reading the narrow track, it may need high TPI capability and the matched filter may generate precise PES continuously or higher bandwidth servo control. Besides, higher sampling rate of amplitude coefficient a₁=(A₁/A₀)_(i), the devices and method according to various embodiments may have ability to compensate the PES error during the recovery of shingle track signal and hence may make the system more tolerate to PES error and relax the need of high bandwidth servo control system. Combination of high PES bandwidth and high sampling rate of amplitude coefficient may make the system more robust in shingle read system.

FIG. 14 shows another phase and amplitude detector scheme 1400. It uses conventional drive servo preamble to achieve phase synchronization and uses additional multifrequency data pattern to determine the amplitude contribution factor of reference track in shingle read track. FIG. 15 shows an illustration 1500 wherein the additional single frequency data pattern is written at the beginning of data sector or at the end of data sector. The adjacent shingle track may write a different frequency for differentiation. Hence a multi-frequency data pattern is formed across the shingle track. In the shingle read track, the amplitude coefficient, a, b, c, d may be estimated through the different frequency burst. In 2 frequency system, the first method to estimate a value may be through iteration. Base on FIG. 15, the signal X₁ is the wide track frequency burst, while signal X₂ is the shingle read track dual frequency signal. By iterating “a” value during subtraction of X₂ to X₁, until the maximum SNR of shingle track T₂ (frequency burst region) is achieved. This condition achieved when the T₁ signal is at minimum in frequency signal. At the beginning of each data track, a frequency burst may be written. For example, a first track T₁ may have a first frequency F₁ and a second track T₂ may have a second frequency F₂. When the head read is at the position in between the 2 tracks (this may be a second read, while we have the first read at T₁ wide track), it may follow the equation shown in FIG. 5 (T₂=X₂−aX₁). At each iteration of subtracting X₂ from X₁(X₁=T₁), the “a” value may be adjusted until the resultant T₂ signal has least component of T₁ signal. This may be reflected in SNR as we the FFT (fast Fourier transform) of F2 may be compared against F1 signal. Another method to estimate amplitude coefficient may be through the amplitude detection of frequency burst. The value may become:

$\begin{matrix} {a = \frac{A_{F\; 1} - A_{F\; 2}}{A_{F\; 1} + A_{F\; 2}}} & (6) \end{matrix}$

FIGS. 16 and 17 showing the de-convolution results from the “a” iteration method. FIG. 16 show the signal image comparison 1600 between wide track data X₁, shingle read track X₂, original shingle track data T₂₋₀, and recover shingle data T₂. The reconstructed shingle track T₂ look alike as original shingle track T₂₋₀. In FIG. 17, a chart 1700 shows that without signal recovery, the shingle read track SNR is 4.76 dB compared to the original shingle track NT31 at 11.97 dB. The wide track signal WT31 may have relatively larger SNR compared to the NT31 as the wide reader will pick up the media noise outside of the narrow track. The reconstructed signals (1 or 2) may have SNR relatively close to the NT31. It shows that the de-convolution scheme according to various embodiments may reproduce a signal of a shingle track.

For the third phase and amplitude coefficient detector scheme, a buried layer dedicated servo system, like will be described in more detail below, may be used to realize the wide reader shingle magnetic recording system. FIG. 18 shows the example 1800 of dedicated multi-frequency servo which may generate both continuous PES and phase synchronization signal. If two frequencies burst F1 and F2 are written in the dedicated servo layer below the data layer, and the reader is position to cover 2 servo track, the read back signal can generate the PES signal by detecting the amplitude of the frequency burst as shown in equation (7).

$\begin{matrix} {{P\; E\; S} = \frac{A_{F\; 1} - A_{F\; 2}}{A_{F\; 1} + A_{F\; 2}}} & (7) \end{matrix}$

It may be a similar concept to equation (6) in determining the amplitude coefficient of reference track. The mixing frequency F1 and F2 together with the low pass filter may generate an output sine wave with frequency F1−F2. This signal may be used as phase synchronization signal.

Besides, phase offset can be detected through the preamble signal as described above. The deconvolution scheme shows in FIG. 9 is to have a wide track as the reference track in a data zone. However, in reading process, it may need to have start reading from the wide track to retrieve the data. It may increase the reading time if only a few data track is needed out of the whole data zone. Hence, a suitable shingle writing scheme 1900 shown in FIG. 19 can be applied to reduce the reading time by increasing the number of wide tracks 1902 in the data zone. For example, at each n shingle narrow write track 1904, a wide track (MTW≧MRW) may be written as the reference signal. This wide track 1902 may serve as the reference track to recover the both sides of narrow shingle read track. This may avoid the need to read the whole data zone if only a small portion of data is need. Besides, this writing scheme may have advantages by limiting the number of narrow shingle track to be recovered with reference to the wide track. For example, the scheme showed in FIG. 19 indicates that at every 2 narrow shingle tracks will have a wide track. Since each wide track may be the reference for both adjacent narrow shingle tracks, the scheme may provide a certain quality of SNR to be maintained in the shingle reading scheme. It may benefit especially to the case where the subsequent narrow recovered track may inherence some signal deterioration. If the signal becomes the next reference track for the next shingle reading track recovery, the error may accumulate and SNR may worsen.

In the following, a buried layer dedicated servo system (for example relating to methods and apparatus for hard-disk drive system operation monitoring and self-adjustment) according to various embodiments will be described.

The following generally relates to data storage devices, and more particularly relates to hard disk drive (HDD) data storage products, including methods and apparatus for monitoring and adjusting the operation thereof.

Hard disk drives include a recordable medium and a head which is mounted to move above the recordable medium as the medium spins. As hard disk drives are designed to smaller and smaller sizes and the medium is designed to store more and more information on narrower and narrower tracks, it is imperative that the relative positions of the rotating medium and the moving head be monitored and other parameters such as relative motion and speed variations be monitored. Such monitoring is needed in order to correct any errors before they become too great. However, today's monitoring techniques are insufficient for the track widths, height tolerances and other parameters.

Thus, what is needed are robust monitoring and self-adjustment techniques for hard disk drives that are compatible with future ultra-thin, greater storage hard disk drives. Furthermore, other desirable features and characteristics will become apparent from the subsequent detailed description, taken in conjunction with the accompanying drawings and this background of the disclosure.

According to the Detailed Description, a method for monitoring hard disk drive operation in a hard disk drive system is provided. The hard disk drive system includes a spindle, a disk and a head. The method includes the steps of writing a wide pattern having a predetermined frequency on a track of a hard disk drive medium, generating a readback signal by reading the wide pattern from the track, processing the read back signal by mixing the read back signal with a reference signal to obtain a summed signal and a difference signal, and filtering the summed signal by a filter centered around the difference signal to generate a measurement signal corresponding to a relative speed change of the spindle and a head-to-disk motion.

In accordance with another aspect of the present embodiment, a method for monitoring operation of a hard disk drive system is presented. The hard disk drive system includes a disk medium including a buried servo layer having a first frequency of data on a first track and a second frequency of data on a second track, the second track adjacent to the first track. The method includes the steps of reading a read back signal by a head positioned at the middle of the first track and the second track, filtering the signal by a first filter centered at the first frequency to extract a first component signal, filtering the signal by a second filter centered at the second frequency to extract a second component signal, combining the first component signal and the second component signal to generate a synchronization signal comprising downtrack information. The downtrack information may include spindle speed variation, spindle speed jitter, and relative head-disk vibration in the downtrack direction.

In accordance with yet another aspect of the present invention, a method for measuring flying height of a head over a disk medium in a hard disk drive (HDD) system is provided. The HDD system includes a disk medium having a buried servo layer with a first frequency of data on a first track and a second frequency of data on a second track, the second track adjacent to the first track. The method includes the steps of reading a readback signal by a head positioned at the middle of the first track and the second track, filtering the signal by a first filter centered at the first frequency to extract a first component signal, filtering the signal by a second filter centered at the second frequency to extract a second component signal, combining the first component signal and the second component signal using Wallace equations to generate a synchronization signal comprising flying height information. A further aspect includes developing a table of operational parameters for various pressures and temperatures from the flying height information for improved HDD system operation.

The following detailed description is merely exemplary in nature and is not intended to limit the invention or the application and uses of the invention. Furthermore, there is no intention to be bound by any theory presented in the preceding background of the invention or the following detailed description of the invention. In this detailed description, three embodiments will be discussed: a novel and improved technique for relative head-disk motion and spindle speed variation measurement, a novel and improved technique for down-track synchronization in a dedicated servo based magnetic recording system, and a novel and improved technique for flying height monitoring in dedicated servo based magnetic recording system.

A new embodiment is presented to measure, in addition to spindle speed variation, the relative head-disk downtrack motion. Unlike conventional approaches such as approaches using hall sensors and rotary encoders or approaches using back electromagnetic field (EMF) measurement for determining spindle speed, the present embodiment uses written-in information on a disk to provide continuous and real-time information about relative head-disk motion, including the effects of relative head-disk vibration. In addition, the present embodiment does not require additional components in a hard disk drive (HDD) implementation except firmware implementation of the present embodiment and a frequency source to be provided by the HDD system on chip (SOC) circuitry.

Current measurement techniques for spindle speed are typically implemented via rotary encoders (optical), hall sensors or measurement of back EMF. For a hard disk drive (HDD) which uses brushless DC (BLDC) motors and performs spindle speed measurement, such measurement can be accomplished through Hall sensors built into the motor. In addition it is also possible, depending on the driving circuitry, to measure spindle speed from back EMF.

However, all these methods provide only information on the rotational speed of the spindle and, therefore, are unable to provide the actual relative head-disk speed or motion which is affected by other effects such as head-disk vibrations. In addition, the need to further increase recording density means that current and future HDDs will move towards very few grains/bit recording. This puts added stress on the ability to write accurately on the magnetic bits. The need for accurate and synchronized writing means that spindle speed variation, jitter and undesired relative head-disk motion and vibration need to be kept very small. At the same time, the ability to accurately measure and quantify such spindle speed variation, jitter and undesired relative head-disk motion and vibration at high resolution becomes very important.

The present embodiment presents a method and approach which can, in addition to measuring the spindle speed and speed variations, also provide measurement for downtrack relative motion and vibration between head and disk at high resolution. Referring to FIG. 20, a diagram 2000 depicts a first approach for real time spindle speed variation and relative headdisk motion measurement. First, a pattern 2002 is written on a track on the disk preferably using a wide writer head. This wide track pattern 2002 will reduce the off-track interference which can degrade a readback signal 2004.

The readback signal 2004 is read back from the wide track pattern 2002 at a frequency f106. Similar to a rotary encoder scheme, the higher the frequency f2006 used, the better the resolution. Since the achievable “encoded” resolution is limited only by a bandwidth of the read-write (RW) head and a disk media combination, a very high frequency in the hundreds of megahertz can be used, enabling an approach which is far superior to any conventional rotary encoder scheme. However, in order to strike a balance between signal to noise ratio and resolution, a frequency of around 80 MHz to 150 MHz for current HDDs is preferred.

Subsequently, the RW head is positioned over the written track 2002 and reads back the written track in a continuous fashion. By using a reference clock signal 2008 at frequency f+Δf and mixing at a mixer 2010 the reference clock signal 2008 with the read back signal at frequency f2012, a mixed signal having signal components at a summed frequency 2f+Δf and a difference frequency Ware obtained.

By using a filter 2014 (e.g., a band pass filter (BPF) or narrow band filter) centered at around frequency Δf a resulting measurement signal 2016 corresponding to relative spindle speed change and head-disk motion is obtained. It is possible to also use a BPF 2014 that is slightly offset from Δf depending on the range of relative speed variation to be measured. The width of the filter 2014 passband may also be a necessary parameter of this embodiment. A sharper (smaller passband) filter 2014 will provide a larger signal change (i.e., more sensitive) for the same relative speed change, but may suffer from a limited range of speeds that can be measured. Thus, a good trade-off between the target range of measurement versus sensitivity is desired to achieve optimal results.

The above approach depicted in the diagram 2000 provides very high resolution. However, one drawback of this approach is that the measurement signal generated is not monotonously increasing or decreasing. Since the signal peaks at a center frequency, the measurement may sometimes be ambiguous. This may be especially true when the measurement range spans to the left and right of the peak, as shown in the signal amplitude vs. RPM graphs 2300, 2350 in FIGS. 23B and 23D.

A second approach is depicted in diagram 2100 of FIG. 21. This second approach alleviates any ambiguity problem that may be present in the first approach by using two matched filters 2104, 2106 instead of a single filter 2014. The steps to generate the readback signal 2012 are the same as the first approach where a wide track of a single frequency is written and mixed at a mixer 2010 with a reference clock signal 2008 of the same writing frequency. However, this second approach provides the resulting mixed signal IF 202 to the two filters 2104, 2106, wherein the first filter 2104 is centered at Δf+f₁ and the second filter 2106 is centered at Δf+f₁ generating the filtered signals A and B, respectively. The frequency f₁ is a frequency passband offset within the bandwidth of the first and second bandpass filters 2104, 2106. A normalization procedure such as (A−B)/(A+B) can then be applied by the combiner 2108 to provide a monotonously increasing signal 2110 over the range of relative spindle speeds to be measured.

Referring to FIG. 22, a graph 2200 further illustrates this second approach. When measured signal Δf is less than Δf 2202, the measured signal Δf moves further into the passband of the B signal 2204 and away from the passband of the A signal 2206. If ΔF is, instead, greater than Δf2202, the measured signai!JF moves into the passband of the A signal 2206 and away from the passband of the B signal 2204. Since the signal A 2206 must increase when the signal B 2204 decreases and vice versa, the resulting signal (A−B)/(A+B) is monotonously increasing for the measurement range between Δf+f₁ and Δf−f₁, thereby removing the ambiguity. Depending on the measurement range required, appropriate f₁ values and filter widths can be chosen for optimal results.

FIG. 23B shows experimental results in the graph 2300 obtained using the first approach for measurements on the air bearing spindle with a measured spindle speed variation of 0.005%. FIG. 23D shows experimental results in the graph 2350 obtained using the first approach for measurements on a HDD product. And FIG. 24B shows experimental results in the graph 2400 when the second approach is used on a HDD product.

The technology and approaches in accordance with the present embodiment can be easily applied to present HDD products. Because no additional components are required except a reference clock and digital filtering, both of which may be easily provided by the HDD system on chip (SOC), large additional costs of implementation are avoided. Also, by implementing the technology into a HDD system and its associated firmware, it is possible to use the technology not only during HDD manufacturing/assembly and in failure analysis situations, but also during normal use by end users.

In the manufacturing and assembly stage, HDD products after assembly could go through a long process of checks including formatting and testing of the media. For very large drives, this could take a long time. Due to manufacturing tolerances and production yields, not all assembled products can work at the same recording density. If the end tested product is found to be unsuitable for a certain recording density, it needs to be downgraded to a lower density level. A test approach in accordance with the present embodiment could be applied, for example, after drive assembly and prior to the formatting and testing step to ascertain the quality of the assembled drive. If at this stage, a drive is found to be of a “lower quality” from measured large speed variations, jitter or relative head-disk vibrations, then the drive can be put to a lower density level immediately. Thus, a simple measurement in accordance with the present embodiment is enabled which could help reduce the manufacturing cost by detecting the quality of the end product earlier without requiring expensive and extensive testing, thereby exemplifying an intelligent manufacturing approach.

The testing approach in accordance with the present embodiment is also useful for the HDD under normal use by end users. For example, it is possible to program the drive for regular self-testing using the testing approach in accordance with the present embodiment. Such self-testing can be performed by the HDD when the drive is idle, thereby serving as a selfreliability check during the HOD's operable life. Any variations in test results can indicate potential drive problems and future failure that need to be fed back to the user for remedial actions before a catastrophic failure actually occurs.

Finally, in a Failure Analysis (FA) situation, the FA process may include running a test in accordance with the present embodiment and examining the test results. A degrade in performance (e.g., increased head-disk vibration or variations in relative spindle speed) could indicate the possible source of a problem to the drive engineer even before a complete teardown is warranted. Thus, the present embodiment can also serve as a quick initial check for the FA process.

In one aspect of the present invention, a method for monitoring hard disk drive operation in a hard disk drive system including a spindle, a disk and head is provided. The method includes the steps of writing a pattern having a predetermined frequency on a wide track of a hard disk drive medium, generating a read back signal by reading the pattern from the track, processing the readback signal by mixing the readback signal with a reference signal to obtain a summed signal and a difference signal, and filtering the summed signal by a filter centered around the difference signal to generate a measurement signal corresponding to a relative speed change of the spindle and a head-to-disk motion.

The monitoring techniques in accordance with the present embodiment advantageously use written-in information on the disk instead of relying on external sensors such as Hall sensors or rotary encoders, thereby enabling the actual head-disk relative speed and motion to be measured instead of only the spindle speed variation (conventional approaches only measure spindle speed but cannot know relative head-disk vibration). Also, the present embodiment can be implemented in firmware on the HDD and does not require additional components like Hall sensors. Only a frequency source is required, and such frequency source can be provided by the HDD system on chip (SOC). Additionally, the written in (“encoded”) track on the disk media can be at a very high frequency, providing robust, high resolution of measurements, the resolution only being limited by the Read/Write (R/W) capability of the head and media combination. Further, the present embodiment can be used in conjunction with existing spindle speed control schemes in HDD, and can be applied to current HDDs as a means for qualification of HDD components (e.g., the spindle).

As HDD technology moves towards fewer grains/bit recording as well as future configurations such as Two Dimensional Magnetic Recording (TDMR) and bit-patterned media, the need to be able to determine the location of the write and read head versus the location of individual bits becomes very important. Thus, the availability of a synchronization signal to determine these locations is paramount. When utilizing a dual frequency dedicated servo media, where the presence of a dedicated servo magnetic layer allows “always on” servo information, the possibility arises to obtain a “continuously on” write synchronization signal. This “continuously on” signal does not only help with accurate writes on location sensitive media but also provides a means to detect and measure down track and spindle vibration, speed and other conditions.

In accordance with a second aspect of the present embodiment, a new configuration is proposed to make use of the frequency based dedicated servo signal to produce an always available write synchronization signal that can allow bit location determination, as well as detection of downtrack vibration, spindle speed variation, and jitter. A dedicated servo layer 2502 located below the data magnetic layer 2504 is shown in the cutaway view 2500 in FIG. 25. Multi-frequency or dual frequency based servo schemes can be utilized in the dedicated servo layer 2502. A slider head 2510 includes a reader head 2512 and a writer head 2514 for reading and writing to the magnetic layers 2502 and 2504. The slider head 2510 also includes a heater 2516 for thermal fly height control (TFC) as known to those skilled in the art. It is important to know the vibration, speed variation and jitter information in order to enable synchronized writing.

Referring to FIG. 26, a top planar view 2600 shows that the reader head 2512 is positioned at the middle of two tracks 2602, 2604 to read back the superposition of the signals from the two servo tracks 2602, 2604 in the dedicated servo layer 2502. The signals from the two servo tracks 2602, 2604 are two separate frequencies as shown in a graph 2606 (i.e., a frequency F1 2608 and a frequency F2 2610).

The process to generate the synchronization signal is given in FIG. 27, including FIGS. 27A and 27B. Referring to FIG. 27A, a block diagram 2700 shows that by applying analog filters or digital filters 2702, 2704 centered at F1 and F2 frequencies 2608, 2610, respectively, to the read back signal 2706 respective frequency components can be extracted, namely frequencies A and B corresponding to the signals from servo tracks f1 2602 and f2 2604, respectively. The signals can be further processed to generate a signal 2708 that can be used for write synchronization write synchronization in, for example, Two Dimension Magnetic Recording (TDMR), as well as for the detection of downtrack vibration, spindle speed variation and jitter.

The readback signal 2706 from the dedicated servo system consists of both a data signal and a servo signal. Referring to FIG. 27B, the F1+F2 signal 2720 from the filters 2702, 2704 (FIG. 27A) is processed using filters 2722, 2724 (either analog bandpass or low pass filters or digital filters) to obtain the F1 and F2 components. The separate F1 and F2 signals are then mixed at a mixer 2726 and filtered by a low pass or band pass filter 2728 to generate a Sine (F1−F2) signal 2730 which constitutes the synchronization signal. As the synchronization signal 2730 is obtained entirely from the written-in dedicated servo signals (F1 and F2), no external reference clock or oscillator is required. This means that the synchronization signal 2730 avoids any phase and frequency drift that is common when an external reference clock is used. At the same time, the synchronization signal 2730 will fully reflect downtrack changes in the HDD system such as spindle speed variation and jitter, and relative head-disk vibration in the down track direction.

FIGS. 28A and B depict three traces 2802, 2804, 2806 that show the simulation results for the generation of the synchronization signal 2730 from the dedicated servo signal. Referring to FIG. 29, simulation results are depicted in a first trace 2900 that illustrates the synchronization signal 2730 is resilient to relative changes in the amplitude of the servo F1 and F2 components which can occur if there is off-track in the read-write head. Essentially by detecting the zero crossing of the AC synchronization signal, effects of off-track which can manifest for example in a different amplitude of the synchronization signal are ignored. A second trace 2950 shows that the synchronization signal 2730 is responsive to a relative phase difference between F1 and F2 components. Referring to FIG. 30, the results 3000 further show the actual spinstand experimental results for generating the synchronization signal 2730, Sine (F1−F2).

The synchronization signal 2730 provides a means to know the location of the read head 2512 in the downtrack direction. For example, the synchronization signal 2730 can be measured and can be translated into a location in the downtrack direction. While a simplified approach counts the number of zero-crossings from the start of a sector or index mark, other methods that can detect phase may also be used. The zero-crossing detector approach is useful because it is not affected by changes in the amplitude of the synchronization signal 2730. By knowing the current location of the read head 2512, it is possible to estimate the location of the write head 2514. With a known location of the write head 2514, synchronized writing utilizing measurements in accordance with the present embodiment can accurately write on targeted magnetic bits.

In addition to synchronized writing, another advantageous use of the synchronization signal 2730 is that it provides information on relative head-disk motion and captures information including undesired jitter, vibration and shock. For example, a deviation or change to the synchronization signal 2730 at a particular instant of time indicates that there is an event that has caused a disturbance in the downtrack direction. Referring to FIG. 31, a graph 3100 shows an example where relative head-disk speed suddenly increased for a short duration, resulting in a detected synchronization signal 2730 that has deviated from the expected or normal signal. By monitoring the synchronization signal 2730 to detect deviations, Δ Sine(F1−F2), it is possible to detect and measure events such as downtrack vibrations or changes in spindle speed.

The ability to monitor downtrack changes and predict downtrack location is advantageous. In the dedicated servo implementation in accordance with the present embodiment, this is even more useful because such monitoring and measurement is available everywhere by virtue of the fact that servo track information is available everywhere on the disk. By implementing the invention into a HDD, for example through firmware in the HDD system on chip (SOC), the monitoring and measurement can become an important tool to detect HDD operational conditions such as excessive shock or vibration and allow the HDD to respond quickly and take preventive action to avoid failure and crash. Regular measurement of the vibration in accordance with the present embodiment can also help to monitor reliability of the drive while in operation. Finally, the present embodiment provides a useful Failure Analysis tool to determine whether the performance of the drive has degraded.

In accordance with this second aspect of the present embodiment, a method for monitoring operation of a hard disk drive system having a disk medium including a buried servo layer having a first frequency of data on a first track and a second frequency of data on a second track, the second track adjacent to the first track, is provided. The method includes the steps of reading a read back signal by a head positioned at the middle of the first track and the second track, filtering the signal by a first filter centered at the first frequency to extract a first component signal, filtering the signal by a second filter centered at the second frequency to extract a second component signal, combining the first component signal and the second component signal to generate a synchronization signal comprising downtrack information. The downtrack information may include spindle speed variation, spindle speed jitter, and relative head-disk vibration in the downtrack direction.

In accordance with the present embodiment, written-in servo information for phase recovery is used. Thus, no additional information or programming is required. In addition, operation in accordance with the present embodiment does not require an external oscillator, thereby avoiding phase drift between a reference frequency and the written-in servo frequency. Also, operation in accordance with the present embodiment is less affected by jitter and spindle speed variation since the (F1−F2) signal follows spindle jitter and speed variations due to using the written-in servo information for timing. Further, the synchronization signal 2730 is resilient to crosstrack and off-track effects (i.e., the AC zero crossing is unaffected by the relative strength of servo components in the dual frequency servo layer). The changes to the synchronization signal 2730 reflect downtrack spindle jitter or speed variations, as well as relative head-disk vibration and shock. Thus, operation in accordance with the present embodiment can help HDD technology to achieve higher linear bits per inch recording which is required to meet continued areal density growth.

In accordance with another aspect of the present embodiment, a new configuration is proposed to make use of a frequency based dedicated servo signal to produce an always available Flying Height (FH) signal with minimum off-track FH variation. This FH signal can be used as an additional monitoring signal for contact detection and HDD reliability.

With the application of thermal Flying Height control (TFC) technology, the Wallace equation based in-situ FH testing technology becomes the major way to measure the FH of Read/Write (R/W) heads. In theory, one single harmonic is good enough to detect the FH variation. But in actual application, the off-track of a read head changes the amplitude of a read back signal and may be misinterpreted as a change in Flying Height. This is one of the major sources of FH testing error. In order to minimize such FH testing error, a harmonic ratio method is typically preferred. It requires a write-in data pattern that can produce at least two harmonics with harmonic signals of sufficient strength for accurate measurement. However, due to the special write-in pattern required on the media, the FH value is not always available in HDDs. Further, conventional FH measurement techniques currently incorporate an acoustic emission (AE) sensor or contact sensor into the magnetic read/write head of a HDD system to detect the contact point. The additional sensor(s) disadvantageously incur additional component cost for the HDD.

In accordance with a third aspect of the present embodiment, the dedicated servo layer 2502 in the HDD disk medium is utilized to provide an always available FH signal and advantageously offers minimization of the effects of off-track FH variation. This FH signal can be used as an additional monitoring signal for contact detection and HDD reliability. Referring back to FIG. 25, the dedicated servo layer 2502 is located below the data magnetic layer 2504 in the disk medium. The flying height (FH) 2530 refers to the height of the head 2510 as it flies over the disk medium. Multiple frequencies or a single frequency of data are stored on the servo tracks of the servo layer 2502. The reader 2512 is positioned at the middle of two track 2602, 2604 to read back the superposition of the signal as shown in FIG. 26. Referring to the block diagram 3200 of FIG. 32, by applying analog or digital filters 2702, 2704, the signal for the respective frequency components can be extracted from the read back signal 2706, and the amplitude of the signals, namely A and B can be determined. The amplitude of the signals can be further processed to produce a position error signal (PES) 3202, the synchronization signal 2708 and a flying height signal 3204.

Based on the Wallace Spacing Loss equation, the spacing Loss is expressed as:

A=e ^(−2πd/λ)  (8)

where A. is the wavelength of the written data pattern and d is the relative change in spacing. Based on the amplitude ratio of the Wallace equation, we can use five different Wallace spacing methods (obtained from equation (8)) to calculate FH from the simultaneous two frequency servo signal. They are:

$\begin{matrix} {{\Delta \; d} = {- \frac{{{\Delta ln}(A)}*\lambda_{A}}{2\; \pi}}} & (9) \\ {{\Delta \; d} = {- \frac{{{\Delta ln}(B)}*\lambda_{B}}{2\pi}}} & (10) \\ {{\Delta \; d} = {- {\frac{{\Delta ln}({AB})}{2\pi}\left\lbrack \frac{\lambda_{A}\lambda_{B}}{\lambda_{B} + \lambda_{A}} \right\rbrack}}} & (11) \\ {{\Delta \; d} = {- {\frac{{\Delta ln}\left( {A\text{/}B} \right)}{2\pi}\left\lbrack \frac{\lambda_{A}\lambda_{B}}{\lambda_{B} - \lambda_{A}} \right\rbrack}}} & (12) \\ {{\ln \left( {A + B} \right)} = {\ln \left\lbrack {^{- \frac{2\pi \; }{\lambda_{A}}} + ^{\frac{2\pi \; }{\lambda_{B}}}} \right\rbrack}} & (13) \end{matrix}$

The above equations are based on ln(A), ln(B), ln(A*B), ln(A/B) and ln(A+B). The respective equations are shown in FIG. 33. It is straightforward to calculate FH based on the first four equations. However, for the case ln(A+B), a more complex equation is needed to calculate FH and d needs to be calculated from a trial and error or iterative approach.

Alternatively, a simple calibration approach can be taken to determine the FH instead of solving the complex equation (13). In this case, we use the ln(A*B) case to calibrate FH for ln(A+B). The calibration equation is shown below:

$\begin{matrix} {{\Delta \; d} = {\frac{{\Delta ln}\left( {A + B} \right)}{{{\Delta ln}\left( {A + B} \right)}_{x}} \times \Delta \; d_{x}}} & (14) \end{matrix}$

where x is the relative TFC applied and Δd_(x) is the corresponding relative FH measured by Δ ln(A*B)_(x). By normalizing the Δ ln(A+B) against Δ ln(A+B)_(x), the FH can be deduced.

FIG. 34, including FIGS. 34A and 34B, shows the touch down curve for respective methods of FH measurement. A graph 3400 in FIG. 34A shows the FH measurement after one hundred times averaging, while a graph 3450 in FIG. 34B indicates an arbitrary instantaneous one point FH measurement. The information depicted in the graph 3450 shows that the FH measured by a single frequency is greatly affected by off-track error. This is further confirmed by the experimental results shown in a graph 3500 of FIG. 35. For these results, the TFC was fixed. It can be seen that the off-track FH variation error can be systematically studied by moving the reader sensor from −20 nm off-center to +20 nm off-center. However, ln(A+B) shows very little off-track FH variation error.

The instantaneous and always available FH signal can also be used as the contact detection sensor. FIG. 36A shows the time domain FH signal. In FIG. 36A, a graph 3600 shows FH signals 3605 and 3615 at different TFC powers. The FH signal 3615 shows a FH signal during normal operation while the vibration FH signal 3605 is clearly observed during the head disk contact at a higher TFC power. FIG. 36B depicts a graph 2620 which plots the root mean square (RMS) of the FH signal at different TFC powers where signals 3622, 3624, 3626 are obtained using ln(A), ln(B) and ln(A+B), respectively. In the graph 2620, the RMS measurements depict a clear sudden increase of value at contact TFC. In some cases, the FH's RMS can even detect the FH vibration prior the AE sensor as shown in a graph 3700 of FIG. 37. This early detection can be attributed to pre-contact slider vibration. All of the above-mentioned FH measurement methods can be used as contact detection. Together with the continuous PES signal 3202, these give a two dimensional and fast response to near contact condition.

As the FH versus TFC actuation curve is different at different altitudes (as shown in a prior art example in graph 3800 of FIG. 38), it is possible to create different FH calibration curves for different altitudes. One way is to calibrate and obtain curves under different air pressures corresponding to the different altitudes.

Subsequently, in actual HDD operation, by moving the operating point through changing the TFC actuation (without going to contact) and measuring the change in FH for each TFC power used, it is possible to determine the gradient, ΔFH/ΔPower_(TFC). This parameter can be used to determine on which altitude curve the drive is operating. If the altitude curve is correctly determined, then appropriate FH look-up tables could be used and unnecessary and undesired head disk contact could be avoided by being able to apply the appropriate TFC power for different altitudes.

The ability to determine the altitude curve on which the drive is working is of great value. In present HDDs, it is difficult to incorporate an altitude sensor. Although drives have temperature sensors (e.g., thermistors), they generally do not have altitude sensors. This means that current HDDs do not know whether they are being operated at a high altitude (e.g., greater than twenty thousand feet) or at sea level. When at a high altitude, the flying height of the head is lower and there is increased chance of head-disk contact and reliability issues if an improper TFC power (such as that suitable for sea level use) is applied.

Appropriate look-up tables for HDD operation under different conditions of pressure (altitude) and temperature can be generated by operation in accordance with the present embodiment. Once these tables are generated, it is possible in accordance with the present embodiment to identify the right look up table to be used in actual drive operation, thus reducing the reliability problems associated with HDD usage at different altitudes. Without calibrated look-up tables for different altitudes, the common approach for current HDDs is to spin down the disk or adjust the TFC such that the head/slider comes into intermittent contact with the disk. Once this is done, the flying height is then known from the amount of TFC actuation applied. However, this touch down approach may wear out the RW heads and also has the risk of head disk damage. Therefore, reduction or elimination of the need to touch down the RW head is enabled by the present embodiment.

Another important advantage of the present embodiment is that the FH information is always available since the servo information is available everywhere for the dedicated servo HDD. Compared to current drives where FH measurement can only depend on a few designated and specially written areas on the disk (if readback signal approach to determine FH is used), the always available FH information for the dedicated servo disk comes at little cost, but brings about great benefits.

In accordance with one aspect of the present invention, a method for measuring flying height of a head over a disk medium in a hard disk drive (HDD) system having a disk medium including a buried servo layer having a first frequency of data on a first track and a second frequency of data on a second track, the second track adjacent to the first track, is provided. The method includes the steps of reading a readback signal by a head positioned at the middle of the first track and the second track, filtering the signal by a first filter centered at the first frequency to extract a first component signal, filtering the signal by a second filter centered at the second frequency to extract a second component signal, combining the first component signal and the second component signal using Wallace equations to generate a synchronization signal comprising flying height information. A second aspect includes developing a table of operational parameters for various pressures and temperatures from the flying height information for improved HDD system operation.

Thus it can be seen that methods for hard disk drive system operation have been disclosed which provides many advantages over the drawbacks of conventional HDDs. While several exemplary embodiments have been presented in the foregoing detailed description of the invention, it should be appreciated that a vast number of variations exist, including variations as to the materials, structure and operation of the data storage device.

It should further be appreciated that the exemplary embodiments are only examples, and are not intended to limit the scope, applicability, dimensions, or configuration of the invention in any way. Rather, the foregoing detailed description will provide those skilled in the art with a convenient road map for implementing an exemplary embodiment of the invention, it being understood that various changes may be made in the function and arrangement of elements and method of play steps described in an exemplary embodiment without departing from the scope of the invention as set forth herein.

According to various embodiments, a method for monitoring hard disk drive operation in a hard disk drive system including a disk having a hard disk medium on a surface thereof and being rotated by a spindle coupled thereto, the hard disk drive system further including a head for writing to and reading from the hard disk medium, may be provided. The method may include: writing a wide track pattern having a predetermined frequency on the hard disk drive medium; generating a readback signal by reading the wide track pattern; processing the read back signal by mixing the readback signal with a reference signal to obtain a mixed signal including a summed signal and a difference signal; and filtering the mixed signal by a filter having parameters determined in response to the difference signal to generate a measurement signal corresponding to a relative speed change of the spindle and a head-to-disk motion.

According to various embodiments, the filtering step may include or may be filtering the mixed signal by a filter centered around the difference signal to generate the measurement signal.

According to various embodiments, the filtering step may include or may be filtering the mixed signal by a filter slightly offset from the difference signal to generate the measurement signal.

According to various embodiments, the generating the readback signal step may include or may be generating the read back signal by reading the wide pattern from the track at a predetermined frequency f.

According to various embodiments, the predetermined frequency f may be a predetermined frequency greater than 50 MHz.

According to various embodiments, the predetermined frequency f may be a predetermined frequency in the range of 80 MHz to 150 MHz.

According to various embodiments, the processing the readback signal step may include or may be processing the readback signal by mixing the read back signal with the reference signal to obtain the mixed signal including the summed signal and the difference signal and wherein the reference signal comprises the predetermined frequency f plus the difference signal.

According to various embodiments, the filtering step may include or may be: filtering the mixed signal by a first bandpass filter having parameters determined in response to the difference signal to obtain a first filtered signal; filtering the mixed signal by a second bandpass filter having parameters determined in response to the difference signal to obtain a second filtered signal; and combining the first filtered signal and the second filtered signal to generate the measurement signal corresponding to the relative speed change of the spindle and the head-to-disk motion.

According to various embodiments, the first bandpass filter and the second bandpass filter may have equivalent bandwidths and wherein the first bandpass filter and the second bandpass filter have non-bandwidth parameters determined in response to the difference signal and a frequency passband offset f₁ within the bandwidth of the first and second bandpass filters.

According to various embodiments, the first bandpass filter may have nonbandwidth parameters determined in response to a sum of the difference signal and the frequency passband offset f₁ and wherein the second bandpass filter has non-bandwidth parameters determined in response to a difference between the difference signal and the frequency passband offset f₁.

According to various embodiments, a method for monitoring operation of a hard disk drive system having a disk medium including a buried servo layer having a first frequency of data on a first track and a second frequency of data on a second track, the second track adjacent to the first track, may be provided. The method may include: reading a readback signal by a head positioned at the middle of the first track and the second track; filtering the signal by a first filter centered at the first frequency to extract a first component signal; filtering the signal by a second filter centered at the second frequency to extract a second component signal; and combining the first component signal and the second component signal to generate a synchronization signal comprising downtrack information.

According to various embodiments, the method may further include the step of utilizing the synchronization signal for write synchronization in Two Dimension Magnetic Recording (TDMR).

According to various embodiments, the downtrack information may include or may be one or more of spindle speed variation information, spindle speed jitter information, and relative head-disk vibration in the downtrack direction information.

According to various embodiments, the data on the first and second tracks may include or may be written-in servo information for phase recovery.

According to various embodiments, a method for measuring flying height of a head over a disk medium in a hard disk drive (HDD) system, wherein the disk medium includes a buried servo layer having a first frequency of data on a first track and a second frequency of data on a second track, the second track adjacent to the first track, may be provided. The method may include: reading a read back signal by a head positioned at the middle of the first track and the second track; filtering the signal by a first filter centered at the first frequency to extract a first component signal; filtering the signal by a second filter centered at the second frequency to extract a second component signal; and combining an amplitude of the first component signal and an amplitude of the second component signal using Wallace equations to generate a synchronization signal comprising flying height information.

According to various embodiments, the method may further include: developing a table of operational parameters for various pressures and temperatures from the flying height information; and utilizing the table of operational parameters for HDD system operation.

Methods and architecture for monitoring hard disk drive operation is provided. The hard disk drive system provided includes a spindle, a head and a disk with a disk medium including a buried servo layer having a first frequency of data on a first track and a second frequency of data on a second track, the second track adjacent to the first track. The method includes the steps of writing a wide track pattern having a predetermined frequency on a track of a hard disk drive medium, generating a readback signal by reading the pattern from the track, processing the readback signal by mixing the readback signal with a reference signal to obtain a mixed signal having a summed signal and a difference signal, and filtering the mixed signal by a filter centered around the difference signal to generate a measurement signal corresponding to a relative speed change of the spindle and a head-to-disk motion. In addition, filtering a read back signal generated by the head when positioned at the middle of the first track and the second track with a first filter centered at the first frequency and a second filter centered at the second frequency is used to generate a synchronization signal for determining spindle speed variation, spindle speed jitter, and relative head-disk vibration in the downtrack direction, for synchronizing writing in Two Dimensional Magnetic Recording (TDMR) and for measuring continuous flying height information based on Wallace equations.

While the invention has been particularly shown and described with reference to specific embodiments, it should be understood by those skilled in the art that various changes in form and detail may be made therein without departing from the spirit and scope of the invention as defined by the appended claims. The scope of the invention is thus indicated by the appended claims and all changes which come within the meaning and range of equivalency of the claims are therefore intended to be embraced. 

What is claimed is:
 1. A system comprising: a reader including a reader head, wherein the reader is configured to (i) receive a first signal from the reader head based on the reader head being at a first position relative to a storage medium, and (ii) receive a second signal from the reader head based on the reader head being at a second position relative to the storage medium, wherein the second position is different from the first position, and wherein each of the first signal and the second signal includes a combination of first data stored in a first track of the storage medium and second data stored in a second track of the storage medium; and a data determination circuit configured to determine third data stored at a predetermined position of the storage medium using (i) the combination of the first data stored in the first track and the second data stored in the second track as received in the first signal, and (ii) the combination of the first data stored in the first track and the second data stored in the second track as received in the second signal.
 2. The system of claim 1, wherein the reader head comprises (i) a first read head configured to receive the first signal and (ii) a second read head configured to receive the second signal.
 3. The system of claim 1, wherein at least one of the first position and the second position overlaps each of the first track and the second track of the storage medium.
 4. The system of claim 3, wherein at least one of the first track and the second track has a width that is less than a width of the reader head of the reader.
 5. The system of claim 1, wherein, to determine the third data, the data determination circuit is configured to determine the third data by performing de-convolution on the first signal and the second signal.
 6. The system of claim 1, wherein (i) the reader is configured to receive a frequency burst signal from the reader head based on the reader head being at a third position relative to the storage medium, and (ii) to determine the third data, the data determination circuit is configured to determine the third data further based on the frequency burst signal.
 7. The system of claim 1, wherein, to determine the third data, the data determination circuit is configured to determine the third data further based on an amplitude coefficient, wherein the amplitude coefficient indicates respective contributions of the first data and the second data.
 8. The system of claim 1, wherein, to determine the third data, the data determination circuit is configured to determine the third data further based on at least one of (i) a phase offset of the first data and (ii) a phase offset of the second data.
 9. The system of claim 1, wherein, to determine the third data, the data determination circuit is configured to (i) calculate a first portion of the first signal received from the first track, (ii) calculate a second portion of the first signal received from the second track, (iii) calculate a third portion of the second signal received from the first track, (iv) calculate a fourth portion of the second signal received from the second track, and (v) determine the third data based on the calculated first portion, second portion, third portion, and fourth portion.
 10. A method, comprising: receiving a first signal from a reader head based on the reader head being at a first position relative to a storage medium; receiving a second signal from the reader head based on the reader head being at a second position relative to the storage medium, wherein the second position is different from the first position, and wherein each of the first signal and the second signal includes a combination of first data stored in a first track of the storage medium and second data stored in a second track of the storage medium; and determining third data stored at a predetermined position of the storage medium using (i) the combination of the first data stored in the first track and the second data stored in the second track as received in the first signal, and (ii) the combination of the first data stored in the first track and the second data stored in the second track as received in the second signal.
 11. The method of claim 10, wherein the reader head includes a first read head and a second read head, wherein receiving the first signal includes receiving the first signal using the first read head, and wherein receiving the second signal includes receiving the second signal using the second read head.
 12. The method of claim 10, wherein receiving the first signal includes positioning the reader head to overlap each of the first track and the second track of the storage medium.
 13. The method of claim 12, wherein at least one of the first track and the second track has a width that is less than a width of the read head.
 14. The method of claim 10, wherein determining the third data includes performing de-convolution on the first signal and the second signal.
 15. The method of claim 10, wherein determining the third data includes (i) receiving a frequency burst signal from the reader head based on the reader head being at a third position relative to the storage medium, and (ii) determining the third data further based on the frequency burst signal.
 16. The method of claim 10, wherein determining the third data includes determining the third data further based on an amplitude coefficient, wherein the amplitude coefficient indicates respective contributions of the first data and the second data.
 17. The method of claim 10, wherein determining the third data includes determining the third data further based on at least one of (i) a phase offset of the first data and (ii) a phase offset of the second data.
 18. The method of claim 10, wherein determining the third data includes (i) calculating a first portion of the first signal received from the first track, (ii) calculating a second portion of the first signal received from the second track, (iii) calculating a third portion of the second signal received from the first track, (iv) calculating a fourth portion of the second signal received from the second track, and (v) determining the third data based on the calculated first portion, second portion, third portion, and fourth portion. 